Integrated chip package structure using ceramic substrate and method of manufacturing the same

ABSTRACT

An integrated chip package structure and method of manufacturing the same is by adhering dies on a ceramic substrate and forming a thin-film circuit layer on top of the dies and the ceramic substrate. Wherein the thin-film circuit layer has an external circuitry, which is electrically connected to the metal pads of the dies, that extends to a region outside the active surface of the dies for fanning out the metal pads of the dies. Furthermore, a plurality of active devices and an internal circuitry is located on the active surface of the dies. Signal for the active devices are transmitted through the internal circuitry to the external circuitry and from the external circuitry through the internal circuitry back to other active devices. Moreover, the chip package structure allows multiple dies with different functions to be packaged into an integrated package and electrically connecting the dies by the external circuitry.

CROSS-REFERENCE TO RELATED APPLICATION This application claims the priority benefit of Taiwan application serial no. 90133092, filed Dec. 31, 2001. BACKGROUND OF THE INVENTION

[0001] 1. Field of the Invention

[0002] The present invention relates to an integrated chip package structure and method of manufacture the same. More particularly, the present invention relates to an integrated chip package structure and method of manufacture the same using ceramic substrate.

[0003] 2. Description of related art

[0004] In the recent years, the development of advanced technology is on the cutting edge. As a result, high-technology electronics manufacturing industries launch more feature-packed and humanized electronic products. These new products that hit the showroom are lighter, thinner, and smaller in design. In the manufacturing of these electronic products, the key component has to be the integrated circuit (IC) chip inside any electronic product.

[0005] The operability, performance, and life of an IC chip are greatly affected by its circuit design, wafer manufacturing, and chip packaging. For this present invention, the focus will be on chip packaging technique. Since the features and speed of IC chips are increasing rapidly, the need for increasing the conductivity of the circuitry is necessary so that the signal delay and attenuation of the dies to the external circuitry are reduced. A chip package that allows good thermal dissipation and protection of the IC chips with a small overall dimension of the package is also necessary for higher performance chips. These are the goals to be achieved in chip packaging.

[0006] There are a vast variety of existing chip package techniques such as ball grid array (B GA), wire bonding, flip chip, etc. . . . for mounting a die on a substrate via the bonding points on both the die and the substrate. The inner traces helps to fan out the bonding points on the bottom of the substrate. The solder balls are separately planted on the bonding points for acting as an interface for the die to electrically connect to the external circuitry. Similarly, pin grid array (PGA) is very much like BGA, which replaces the balls with pins on the substrate and PGA also acts an interface for the die to electrically connect to the external circuitry.

[0007] Both BGA and PGA packages require wiring or flip chip for mounting the die on the substrate. The inner traces in the substrate fan out the bonding points on the substrate, and electrical connection to the external circuitry is carried out by the solder balls or pins on the bonding points. As a result, this method fails to reduce the distance of the signal transmission path but in fact increase the signal path distance. This will increase signal delay and attenuation and decrease the performance of the chip.

[0008] Wafer level chip scale package (WLCSP) has an advantage of being able to print the redistribution circuit directly on the die by using the peripheral area of the die as the bonding points. It is achieved by redistributing an area array on the surface of the die, which can fully utilize the entire area of the die. The bonding points are located on the redistribution circuit by forming flip chip bumps so the bottom side of the die connects directly to the printed circuit board (PCB) with micro-spaced bonding points.

[0009] Although WLCSP can greatly reduce the signal path distance, it is still very difficult to accommodate all the bonding points on the die surface as the integration of die and internal devices gets higher. The pin count on the die increases as integration gets higher so the redistribution of pins in an area array is difficult to achieve. Even if the redistribution of pins is successful, the distance between pins will be too small to meet the pitch of a printed circuit board (PCB).

SUMMARY OF THE INVENTION

[0010] Therefore the present invention provides an integrated chip package structure and method of manufacturing the same that uses the original bonding points of the die and connect them to an external circuitry of a thin-film circuit layer to achieve redistribution. The spacing between the redistributed bonding points matches the pitch of a PCB.

[0011] In order to achieve the above object, the present invention presents an integrated chip package structure and method of manufacturing the same by adhering the backside of a die to a ceramic substrate, wherein the active surface of the die has a plurality of metal pads. A thin-film circuit layer is formed on top of the die and the ceramic substrate, where the thin-film circuit layer has an external circuitry that is electrically connected to the metal pads of the die. The external circuitry extends to a region that is outside the active area of the dies and has a plurality of bonding pads located on the surface layer of the thin-film layer circuit. The active surface of the die has an internal circuitry and a plurality of active devices, where signals can be transmitted from one active device to the external circuitry via the internal circuitry, then from the external circuitry back to another active device via the internal circuitry. Furthermore, the ceramic substrate has at least one inwardly protruded area so the backside of the die can be adhered inside the inwardly protruded area and exposing the active surface of the die. Wherein the ceramic substrate is composed of a ceramic layer and a heat conducting material formed overlapping and the inwardly protruded areas are formed by overlapping the ceramic substrate with openings on the heat conducting layer. Furthermore, the present chip package structure allows multiple dies with same or different functions to be packaged into one integrated chip package and permits electrically connection between the dies by the external circuitry.

[0012] It is to be understood that both the foregoing general description and the following detailed description are exemplary, and are intended to provide further explanation of the invention as claimed.

BRIEF DESCRIPTIOIN OF THE DRAWINGS

[0013] The accompanying drawings are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification. The drawings illustrate embodiments of the invention and, together with the description, serve to explain the principles of the invention. In the drawings,

[0014]FIGS. 1A to 1I are schematic diagrams showing the sectional view of the structure of the first embodiment of the present invention.

[0015]FIGS. 2A to 2C are schematic diagrams showing the sectional view of the structure of the second embodiment of the present invention.

[0016]FIGS. 2D to 2E are schematic diagrams showing the section view of the formation of inwardly protruded areas in the organic substrate of the structure of the second embodiment of the present invention.

[0017]FIGS. 3A to 3C are schematic diagrams showing the sectional view of the structure of the third embodiment of the present invention.

[0018]FIGS. 4A to 4I are schematic diagrams showing the sectional view of the structure of the forth embodiment of the present invention.

[0019]FIGS. 5A to 5E are schematic diagrams showing the sectional view of the structure of the fifth embodiment of the present invention.

[0020]FIG. 6 is a schematic diagram showing the section view of the chip package structure of a preferred embodiment of the present invention with one die.

[0021]FIG. 7 is a schematic diagram showing the section view of the chip package structure of a preferred embodiment of the present invention with a plurality of dies.

[0022]FIG. 8 is a magnified diagram showing the sectional view of the chip package structure of a preferred embodiment of the present invention.

[0023]FIGS. 9A, 9B are schematic diagrams of the top and side view respectively of the patterned wiring layer of the thin-film circuit layer with a passive device.

[0024]FIG. 10A is a schematic diagram of the formation of a passive device by a single layer of patterned wiring layer of the thin-film circuit layer.

[0025]FIG. 10B is a schematic diagram of the formation of a passive device by a double layer of patterned wiring layer of the thin-film circuit layer.

[0026]FIG. 11A is a schematic diagram of the formation of a passive device by a single layer of patterned wiring layer of the thin-film circuit layer.

[0027]FIG. 11B is a schematic diagram of the formation of a passive device by a double layer of patterned wiring layer of the thin-film circuit layer.

[0028]FIG. 11C is a schematic diagram of the formation of a passive device by a double layer of patterned wiring layer of the thin-film circuit layer.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIEMENTS

[0029] Please refer to FIG. 1A, a ceramic substrate 110 with a surface 112 usually of aluminum oxide material or other ceramic material is provided. A plurality of dies 120 having an active surface 122 and a backside 124 is also provided, where the active devices are formed on active surface 122 of the dies. Furthermore, dies 120 have a plurality of metal pads 126 located on active surface 122 of dies 120 acting as the output terminal of dies 120 to transmit signals to the external circuitry. Backside 124 of dies 120 is adhered to surface 112 of ceramic substrate 110 by a conductive paste or adhesive tape. Therefore, active surface 122 of dies 120 is facing upwards along surface 112 of ceramic substrate 110.

[0030] Please refer to FIG. 1B, when adhering die 120 to ceramic substrate 110, a filling layer 130 can be formed on top of surface 112 of ceramic substrate 100 surrounding the peripheral of dies 120 to fill the gap between dies 120. The height of filling layer 130 should be approximately equal to the height of active surface 122 of dies 120. The material of filling layer 130 can be epoxy, polymer, or the like. After curing of filling layer 130, a grinding or etching process is applied to planarize filling layer 130 so the top face of filling layer 130 is planar with active surface 122 of dies 120.

[0031] Please refer to FIG. 1C, after the formation of filling layer 130 on ceramic substrate 110, a dielectric layer 142 is formed on top of filling layer 130 and active surface 122 of dies 120. Dielectric layer 142 is patterned according to metal pads 126 on dies 120 to form thru-holes 142 a. The material of dielectric layer 142 can be poly-Imide (PI), benzocyclobutene (BCB), porous dielectric material, stress buffer material, or the like. Patternization of dielectric layer 142 can be performed by photo via, laser ablation, plasma etching, or the like.

[0032] Please continue to refer to FIG IC, filling layer 130 is used to support dielectric layer 142 so dielectric layer 142 can be formed planarized on top of ceramic substrate 110 and dies 120 without an uneven surface. As a result, after dielectric layer 142 is formed on surface 112 of ceramic substrate 110 and active surface 122 of die 120, dielectric layer 142 also fills the peripheral of dies 120, meaning the gap between dies 120. Therefore the bottom structure of dielectric layer 142 can replace the structure of filling layer 130 covering entirely surface 112 of ceramic substrate 110 and surrounding dies 120. The method of forming dielectric layer 142 includes first depositing a layer of dielectric layer 142 entirely over dies 120 and ceramic substrate 110, then after curing, a grinding or etching process is performed to planarize dielectric layer 142.

[0033] Please refer to FIG. 1D, after forming dielectric layer 142 and patterning dielectric layer 142 to form thru-holes 142 a, a patterned wiring layer 144 is formed on top of dielectric layer 142 by photolithography and sputtering, electroplating, or electro-less plating. Wherein part of the conductive material from patterned wiring layer 144 will be injected into thru-holes 142 a to form vias 142 b, copper (Cu) is used as the material for patterned wiring layer 144. Moreover, thru-holes 142 a can be pre-filled with a conductive material such as a conductive glue to form vias 142 b. Therefore no matter if the thru-holes are filled with the conductive material from patterned wiring layer 144 or pre-filled with a conductive material, patterned wiring layer 144 is electrically connected to metal pads 126 of dies 120. It is to be noted that part of patterned wiring layer 144 extends to a region outside active surface 122 of dies 120. Dielectric layer 142 and patterned wiring layer 144 form a thin-film circuit layer 140.

[0034] Please refer to FIG. 1E, after the formation of patterned wiring layer 144, another dielectric layer 146 can be formed similarly to dielectric layer 142 on top of dielectric layer 142 and patterned wiring layer 144. Dielectric layer 146 is also patterned to form thru-holes 146 a, whereas thru-holes 146 a correspond to bonding pads 144 a of patterned wiring layer 144.

[0035] Please refer to FIG. 1F, after the formation and patternization of dielectric layer 146 to form thru-holes 146 a, a patterned wiring layer 148 can be formed on dielectric layer 146 in a similar way as patterned wiring layer 144. Wherein part of the conductive material from patterned wiring layer 148 will be injected into thru-hole 146 a forming a via 146 b. By the same token, patterned wiring layer 148 is electrically connected to patterned wiring layer 144 by vias 146 b, and further electrically connected to metal pads 126 of die 120 by vias 142 b of thru-hole 142 a. Therefore, thin-film circuit layer 140 further comprises dielectric layer 146, a plurality of vias 146 b, and patterned wiring layer 148.

[0036] Please continue to refer to FIG. 1F, in order to redistribute all metal pads 126 of dies 120 on ceramic substrate 110, the number of patterned wiring layers (144, 148 . . . ) and dielectric layers (142, 146 . . . ) for electrical insulation may be increased. All patterned wiring layers (144, 148 . . . ) are electrically connected by vias (146 b . . . ) of thru-holes (146 a . . . ). However if only the first patterned wiring layer 144 is required to entirely redistribute metal pads 126 of dies 120 on ceramic substrate 110, extra dielectric layers (146 . . . ) and patterned wiring layers (148 . . . ) will no longer be required in the structure. In other words, thin-film circuit layer 140 comprises at least one dielectric layer 142, one patterned wiring layer 144, and a plurality of vias 142 b. Wherein patterned wiring layer (144, 148 . . . ) and vias (142 b, 146 b . . . ) of thin-film circuit layer 140 form an external circuitry of thin-film circuit layer 140.

[0037] Please refer to FIG. 1G, after the formation of patterned wiring layer 148, a patterned passivation layer 150 is formed on top of dielectric layer 146 and patterned wiring layer 148. Patterned passivation layer 150 is used to protect patterned wiring layer 148 and expose the plurality of bonding pads 148 a of patterned wiring layer 148, whereas some of bonding pads 148 a are in a region outside active surface 122 of dies 120. As previously mentioned, the redistribution of metal pads 126 on ceramic substrate 110 requires multiple layers of patterned wiring layers (144, 148 . . . ) and a patterned passivation layer 150 formed on the very top, which is furthest away from ceramic substrate 110. However, if only patterned wiring layer 144 is required to redistribute metal pads 126 of dies 120 on ceramic substrate 110, patterned passivation layer 150 will be formed directly on patterned wiring layer 144. The material of passivation layer 150 can be anti-solder insulating coating or other insulating material.

[0038] Please refer to FIG. 1H, after the formation of patterned passivation layer 150, a bonding point 160 can be placed on bonding pads 148 a serving as an interface for electrically connecting die 120 to the external circuitry. Wherein bonding point 160 illustrated in FIG. 1H is a ball but it is not limited to any formation, which might include a bump, pin, or the like. Ball connector maybe solder ball, and bump connector maybe solder bump, gold bump, or the like.

[0039] Please refer to FIG. 11, after the formation of bonding points 160 on bonding pads 148 a, a singularization process of packaged die 120 by mechanical or laser cutting is performed along the dotted line as indicated in the diagram. Afterwards, the chip package structure of the die is completed.

[0040] According to the above, the first embodiment of the present invention is a chip package structure with a ceramic substrate and a plurality of dies on it. The external circuitry of the thin-film circuit layer allows the metal pads of the die to fan out. By forming bonding pads corresponding to the metal pads of the dies such as solders balls, bumps, or pins as the signal input terminals, the distance of the signal path is effectively decreased. As a result, signal delay and attenuation are reduced to increase performance of the die.

[0041] Ceramic material possesses advantageous properties such as high structural rigidity, high anti-corrosive properties, high density, and high thermal conductivity. Coefficient of thermal expansion (CTE) of aluminum oxide ceramic material is comparable to that of iron-cobalt-nickel alloy. The present invention specifically applies the use of ceramic material due to its high structural rigidity, high anti-corrosive properties, high density, and high thermal conductivity, which means that the package structure can be used in unfavorable environments such as high-corrosiveness, high humidity, or high temperature environment. The high CTE of ceramic material will help the dies to dissipate heat for improved performance. Furthermore, the fabrication of ceramic-BGA (CBGA) substrate is already well know in the art, therefore current manufacturing machines can be easily adapted to manufacture the ceramic substrate of the present invention for lower cost.

[0042] The second embodiment of the present invention differs from the first embodiment by having inwardly protruded areas in the ceramic substrate. This area is for placement of the die with the backside of the die adhered to the bottom of the area so the overall thickness of the chip package structure is reduced. FIGS. 2A to 2C are schematic diagrams of the sectional view of the second embodiment illustrating the fabrication of the structure.

[0043] Please refer to FIG. 2A, a ceramic substrate 210 with a surface 212 is provided. In FIG. 2B, a plurality of inwardly protruded areas 214 is formed on ceramic substrate 210 by machining such as milling. The depth of each inwardly protruded area 214 is approximately equal to the thickness of die 220, therefore the outline and depth of inwardly protruded areas 214 will be the same as dies 220 in FIG. 2C. In FIG. 2C, backside 224 of dies 220 is adhered to the bottom of inwardly protruded areas 214 so dies 220 are inlayed in inwardly protruded areas 214. Active surface 222 of die 220 is exposed along surface 212 or ceramic substrate 210.

[0044] An alternative method of forming inwardly protruded areas 214 in ceramic substrate 210 in FIG. 2B is to use two green sheets 210 a and 210 b that are not sintered, as illustrated in FIG. 2D. Green sheet 210 a has openings 214 a and by overlapping the two green sheets 210 a, 210 b and sintering them at a high temperature, opening 214 a in green sheet 210 a will form inwardly protruded areas 214 on green sheet 210 b as seen before in FIG. 2B, illustrated in FIG. 2E. The thickness of green sheet 210 a is approximately equal to that of die 220 so the depth of inwardly protruded areas 214 is approximately equal to the thickness of die 220.

[0045] Furthermore, in FIGS. 2D and 2E, the two green sheets 210 a and 210 b provided can be already sintered before putting together. Openings 214 a can be formed before or after sintering green sheet 210 a. Following, the two green sheet 210 a, 210 b are overlapped to form inwardly protruded openings 214 in ceramic substrate 210.

[0046] The structure of the second embodiment of the present invention after FIG. 2C will follow FIGS. 1C to 1I from the first embodiment of the present invention, therefore it will not be repeated.

[0047] The second embodiment of the present invention is a ceramic substrate with a plurality of inwardly protruded areas for inlaying dies by adhering the backside of the dies to the bottom of the inwardly protruded areas and exposing the active surface of the dies. A thin-film circuit layer is formed on top of the dies and the ceramic substrate to fan out the metal pads of the dies by using the external circuitry of the thin-film circuit layer. Due to the inlay of the dies in the ceramic substrate, thinning of the thickness of the chip package structure is effectively achieved and the surface of the ceramic substrate provides enough planarity and support for the formation of the thin-film circuit layer.

[0048] The third embodiment of the present invention differs from the second embodiment of the present invention by using an integrated ceramic substrate with at least one ceramic layer and one heat conducting layer. FIGS. 3A to 3C are schematic diagrams of the sectional view of the third embodiment illustrating the fabrication of the structure.

[0049] Please refer to FIG. 3A, an integrated ceramic substrate 310 consists of a ceramic layer 310 a with multiple openings 314 a and a heat conducting layer 310 b, wherein the material of heat conducting layer 310 b maybe metal. In FIG. 3B, ceramic layer 310 a is placed overlapping heat conducting layer 310 b so openings 314 a of ceramic layer 310 a form inwardly protruded areas 314. Following in FIG. 3C, backside 324 of die 320 is adhered to the bottom of inwardly protruded areas 314 so dies 320 are inlayed in ceramic substrate 310 with active surface 322 of die 320 exposed along surface 312 of ceramic board 310.

[0050] The following presents two ways of forming integrated ceramic substrate 310 with inwardly protruded areas 314 as shown in FIG. 3B. In FIG. 3A, a non-sintered ceramic layer (green sheet) 310 a with openings 314 a is provided, and in FIG. 3B, the non-sintered ceramic layer 310 a is overlapped on heat conductive layer 310 b so openings 314 a of ceramic layer 310 a can form inwardly protruded areas 314 on the surface of heat conducting layer 310 b. Afterwards, integrated ceramic substrate 310 with ceramic layer 310 a and heat conducting layer 310 b are sintered at a temperature above 1000° C. Therefore the material of heat conducting layer 310 b must have a higher melting temperature than the temperature used for sintering the green sheet.

[0051] The alternative method is using an already-sintered ceramic layer 310 a with openings 314 a. The already-sintered ceramic substrate layer 310 a is overlapped on heat conducting layer 310 b so openings 314 a of ceramic layer 310 a can form inwardly protruded areas 314. The thickness of ceramic layer 310 a is approximately equal to that of die 320 so the depth of openings 314 a is also approximately equal to the thickness of die 320.

[0052] The structure of the third embodiment of the present invention after FIG. 3C will follow FIGS. 1C to 1I from the first embodiment of the present invention, therefore it will not be repeated.

[0053] The third embodiment of the present invention is an integrated ceramic substrate with a ceramic layer with a plurality of openings and a heat conducting layer. The openings in the ceramic layer will form inwardly protruded areas on the integrated ceramic substrate. Backside of the die adheres to the bottom of the inwardly protruded areas so the dies are inlayed in the inwardly protruded areas exposing the active surface of the dies. This integrated ceramic substrate can efficiently dissipate heat from the dies to the outside because the bottom of the inwardly protruded area is the surface of the heat conducting material. The surface of the ceramic substrate provides enough planarity and support for the formation of the thin-film circuit layer.

[0054] The fourth embodiment of the present invention is slightly different from the first three embodiments. FIGS. 4A to 4E are schematic diagrams of the sectional view of the fourth embodiment illustrating the fabrication of the structure.

[0055] Please refer to FIG. 4A, a ceramic substrate 410 with a first surface 412 and a plurality of dies 420 are provided. The dies 420 have an active surface 422, a backside 424, and a plurality of metal pads 426 located on active surface 422. The fourth embodiment of the present invention differs from the third embodiment of the present invention by placing active surface 422 of die 420 downwards facing first surface 412 of ceramic substrate 410.

[0056] Please refer to FIG. 4B, a filling layer 430 is formed on top of first surface 412 of ceramic substrate 410 after active surface 422 of die 420 is adhered to first surface 412 of ceramic substrate 410. Filling layer 430 covers entirely first surface 412 of ceramic substrate 410 and surrounds dies 420. The material of filling layer 430 maybe an oxide, epoxy, or the like.

[0057] Please refer to FIG. 4C, after the formation of filling layer 430, a planarization process such as grinding is performed to planarize filling layer 430 and backside 424 of dies 420. Although the thickness of the active devices and wiring (not shown) on active surface 422 of die 420 is much less than that of dies 420, the thickness of die 420 should not be too small because cracks or damage to the die will occur during machine handling. However the present invention directly adheres active surface 422 of dies 420 to first surface 412 of ceramic substrate 410 without further machine handling. Afterwards a grinding process is performed on backside 424 of dies 420 to reduce the thickness of dies 420. As a result, dies 420 are ground to a very small thickness allowing the final chip package structure to be much thinner.

[0058] Please refer to FIG. 4D, after the planarization of filling layer 430 and dies 420, a second ceramic substrate 440 with a second surface 442 is adhered to filling layer 430 and dies 420 creating a sandwich effect with filling layer 430 and dies 420 in between two ceramic substrates 410 and 440.

[0059] Please refer to FIG. 4E, after the adhesion of second ceramic substrate 440, a grinding or the like process is performed to thin the backside of ceramic substrate 410 to achieve a thickness of about 2 microns to 200 microns, usually about 20 microns. First ceramic substrate 410 is used to provide a planar surface for dies 420 to adhere to and to serve as an insulating layer. Therefore ceramic substrate 410 can be replaced by substrate made of glass or other organic material.

[0060] Please refer to FIG. 4F, after the thinning of first ceramic substrate 410, a plurality of first thru-holes 410 a are formed on first ceramic substrate 410 for exposing metal pads 426 of active surface 422 of die 420. First thru-holes 410 a can be formed by machine drilling, laser, plasma etching, or similar methods.

[0061] Please refer to FIG. 4G, a first patterned wiring layer 450 is formed on first ceramic substrate 410. Using the same method disclosed in the first embodiment of the present invention, first vias 410 b in first thru-holes 410 a are formed by either filling first thru-holes 410 a with part of the conductive material from patterned wiring layer 450 or pre-filling first thru-holes 410 a with a conductive material before the formation of patterned wiring layer 450. A part of patterned wiring layer 450 will extend to a region outside active surface 422 of die 420.

[0062] Please refer to FIG. 4H, a dielectric layer 462 is formed on first ceramic substrate 410 and first patterned wiring layer 450. Wherein dielectric layer 462 is patterned to form a plurality of second thru-holes 462 a, which correspond to bonding pad 450 a of patterned wiring layer 450.

[0063] Please refer to FIG. 41, a second patterned wiring layer 464 is formed on dielectric layer 462. Using the same method as above, second vias 462 b in second thru-holes 462 a can be formed by either filling second thru-holes 462 a with part of the conductive material from patterned wiring layer or pre-fill second thru-holes 462 a with a conductive material before the formation of patterned wiring layer 464. Similarly, in order to redistribute metal pads 426 of dies 420 on second ceramic substrate 440, dielectric layer (462 . . . ), second vias (462 a . . . ), and second patterned wiring layer (464 . . . ) can be repeatedly formed on dies 420 and second ceramic substrate 440. Wherein first ceramic substrate 410, first patterned wiring layer 450, dielectric layer 462 . . . , and second patterned wiring layer 464 . . . form thin-film circuit layer 460. First vias 410 b, first patterned wiring layer 450, second vias 462 b . . . , and second patterned wiring layer 464 form the external circuitry of thin-film circuit layer 460.

[0064] The structure of the fourth embodiment of the present invention after FIG. 41 will follow FIGS. 1G to 1I from the first embodiment of the present invention, therefore it will not be repeated.

[0065] The fourth embodiment of the present invention is a ceramic substrate with the active surface of the dies directly adhered to the surface of the first ceramic substrate. A filling layer is formed over the dies and the ceramic substrate followed by a planarization and thinning process. Afterwards, a second ceramic substrate is adhered to the die and the filling layer. A thinning process of the first ceramic substrate is performed and a plurality of thru-holes filled with conductive material are formed on the first ceramic substrate. Finally a patterned wiring layer is formed on the first ceramic substrate allowing the external circuitry of the thin-film circuit layer to extend to a region outside the active surface of the die to help fan out the metal pads of the die.

[0066] The advantage of this structure is increased surface stability and accuracy because the active surface of the dies are first adhered to the surface of the first ceramic substrate. The thickness of the die can be very small for reducing the overall thickness of the chip package because no machine handling of dies is required.

[0067] The fifth embodiment of the present invention takes the first half of the fabrication process from the fourth embodiment of the present invention and combines with the second half of the fabrication process from the first embodiment of the present invention. FIGS. 5A to 5E are schematic diagrams of the sectional view illustrating the fabrication of the structure.

[0068] Please refer to FIG. 5A, an active surface 522 of dies 520 is adhered to a first surface 512 of a first ceramic substrate 510. In FIG. 5B, a filling layer 530 is formed on top of dies 520 and first ceramic substrate 510 covering dies 520. In FIG. 5C, a planarization and thinning process of dies 520 and filling layer 530 is performed to planarize backside 524 of dies 520 and filling layer 530. In FIG. 5D, a second ceramic substrate 540 is formed on top of dies 520 and filling layer 530 so backside 524 of dies 520 adheres to second ceramic substrate 540. By removing filling layer 530 and first ceramic substrate 510, the metal pads on active surface 522 of dies 520 are exposed. First ceramic substrate 510 is used to supply a planarized surface (first surface 512), and will be removed in later stages of the fabrication process. Therefore first ceramic substrate 510 can be replaced by substrates of other materials such as glass, metal, silicon, or other organic material.

[0069] The structure of the fifth embodiment of the present invention after FIG. 5E will follow FIGS. 1B to 1I of the first embodiment of the present invention, therefore it will not be repeated.

[0070] The fifth embodiment of the present invention is a ceramic substrate with the active surface of the die adhered to the surface of the first ceramic substrate for allowing high surface stability and accuracy. As a result, it eliminates the need of machine handling of the dies to achieve a very small thickness of the die for reducing the overall thickness of the chip package.

[0071] Furthermore, please refer to FIG. 6, it illustrates the schematic diagram of the sectional view of the chip package structure 600 of the present invention for a single die 620. Die 620 is placed on ceramic substrate 610, and a thin-film circuit layer 640 is formed on top of dies 620 and ceramic substrate 610. External circuitry 642 of thin-film circuit layer 640 has at least has one patterned wiring layer 642 a and a plurality of vias 642 b. The thickness of the inner traces inside die 620 is usually under 1 micron, but because the high amount of traces collocated together so RC delay is relatively high and the power/ground bus requires a large area. As a result, the area of die 620 is not enough to accommodate the power/ground bus. Therefore the chip package structure 600 uses thin-film circuit layer 640 and external circuitry 642 with wider, thicker, and longer traces to alleviate the problem. These traces act an interface for transmitting signals for the internal circuitry of die 620 or the power/ground bus of die 620. This will improve the performance of die 620.

[0072] Please refer to FIG. 8, it illustrates a magnified view of the sectional view of the chip package structure of the present invention. Active surface 622 of die 620 has a plurality of active devices 628 a, 628 b, and an internal circuitry 624. The internal circuitry 624 forms a plurality of metal pads 626 on the surface of die 620. Therefore signals are transmitted from active devices 628 a to external circuitry 642 via internal circuitry 624 of die 620, and from external circuitry 642 back to another active device 628 b via internal circuitry 624. The traces of external circuitry 642 are wider, longer, and thicker than that of internal circuitry 624 for providing an improved transmission path.

[0073] Please continue to refer to FIG. 6, external circuitry 642 further comprises at least one passive device 644 including a capacitor, an inductor, a resistor, a wave-guide, a filter, a micro electronic mechanical sensor (MEMS), or the like. Passive device 644 can be located on a single layer of patterned wiring layer 642 a or between two layers of patterned wiring layers 642 a. In FIGS. 9A, 9B, passive device 644 can be formed by printing or other method on two bonding points on patterned wiring layer 642 a when forming thin-film layer 640. In FIG. 10A, a comb-shape passive device 644 (such as a comb capacitor) is formed directly on a single patterned wiring layer. In FIG. 10B, passive device 644 (such as a capacitor) is formed between two layers of patterned wiring layers 642 a with an insulating material 646 in between. Wherein the original dielectric layer (not shown) can replace insulating material 646. In FIG. 11A, passive device 644 (such as an inductor) is formed by making a single layer of patterned wiring layer 642 a into a circular or square (not shown) spiral. In FIG. 11B, column-shape passive device 644 (such as an inductor) is formed by using two layers of patterned wiring layers 642 a and a plurality of vias 642 b to surround an insulating material 646 forming a column. In FIG. 11C, circular-shaped passive device 644 (such as an inductor) is formed by using slanted traces from two layers of patterned wiring layers and a plurality of vias 642 b to surround an insulating material 646 in a circular manner forming a pie. The above structures allow the original externally welded passive devices to be integrated into the inside of the chip package structure.

[0074]FIG. 6 illustrates a chip package structure 600 for a single die 620 but FIG. 7 illustrates a chip package structure 700 for a plurality of dies. Chip package structure 700 in FIG. 7 differs from chip package structure 600 in FIG. 6 by having a die module 720, which comprises at least one or more dies such as die 720 a, 720 b. Die 720 a, 720 b are electrically connected by the external circuitry of the thin-film circuit layer. The function of die 720 a, 720 b can be the same or different and can be integrated together by external circuitry 742 to form a multi-die module (MCM) by packaging same or different dies into one chip package structure. When multiple dies are packaged into the same chip package structure, singulation process is performed on the determined number of dies.

[0075] Following the above, the present invention provides a chip packaging method by adhering a die to a ceramic substrate or to an inwardly protruded area of a ceramic substrate, and forming a thin-film circuit layer with bonding pads and points above the die and ceramic substrate. This structure can fan out the metal pads on the die to achieve a thin chip package structure with high pin count.

[0076] Comparing to the BGA or PGA package technique used in the prior art, the chip package of the present invention is performed directly on the die and the ceramic substrate for fanning out the metal pads on the die. It does not require flip chip or wire bonding to connect the die to the micro-spaced contact points of a package substrate or carrier. The present invention can reduce cost because the package substrate with micro-spaced contacts is very expensive. Moreover the signal transmission path of the present invention is reduced to lessen the effect of signal delay and attenuation, which improves the performance of the die.

[0077] Furthermore, the present invention uses ceramic substrate with high structural rigidity, high anti-corrosive properties, high density, and high thermal conductivity, which means that the package structure can be used in unfavorable environments such as high-corrosive, high humidity, or high temperature environment. The high CTE of ceramic material will help the die dissipate heat to improve performance. Furthermore, ceramic-BGA (CBGA) is already well know in the skilled of the art, which can be adapted to current machines to manufacture the ceramic substrate of the present invention for lower cost.

[0078] Furthermore, the third embodiment of the present invention provides an integrated substrate comprises a ceramic layer and a heat conducting layer. A plurality of openings can be pre-formed on the ceramic layer so inwardly protruded areas are formed for inlaying the die when the ceramic layer overlaps the heat conducting layer. The heat conducting layer helps to dissipate heat to the outside from the die during operation, which will effectively increase performance.

[0079] The thin-film layer circuit of the present invention is used to transmit signals between two main active devices inside the die, or used as a power/ground bus, or used to add in passive devices. Furthermore, the chip package structure of the present invention can accommodate one or more dies with similar or different functions. The external circuitry of the thin-film circuit layer electrically connects the multiple dies together and can be used in a MCM package. The chip package structure of the present invention adapts the MCM, the external circuitry of the thin-film circuit layer, the passive devices of the external circuitry to form a package that is “system in package”.

[0080] It will be apparent to those skilled in the art that various modifications and variations can be made to the structure of the present invention without departing from the scope or spirit of the invention. In view of the foregoing, it is intended that the present invention cover modifications and variations of this invention provided they fall within the scope of the following claims and their equivalents. 

What is claimed is:
 1. A chip package structure comprising: a ceramic substrate; a die, wherein the die has an active surface, a backside that is opposite to the active surface, and a plurality of metal pads located on the active surface, whereas the backside of the die is adhered to the ceramic substrate; and a thin-film circuit layer located on top of the ceramic substrate and the die and has an external circuitry, wherein the external circuitry is electrically connected to the metal pads of the die and extends to a region outside the active surface of the die, the external circuitry has a plurality of bonding pads located on a surface layer of the thinfilm circuit layer and each bonding pad is electrically connected to the corresponding metal pad of the die.
 2. The structure in claim 1, wherein the die has an internal circuitry and a plurality of active devices located on the active surface of the die and the internal circuitry is electrically connected to the active devices, whereas the internal circuitry forms the metal pads.
 3. The structure in claim 2, wherein a signal from one of the active devices is transmitted to the external circuitry via the internal circuitry, and from the external circuitry back to one of the active devices via the internal circuitry.
 4. The structure in claim 3, wherein a width, length, and thickness of traces of the external circuitry are greater than corresponding traces of the internal circuitry.
 5. The structure in claim 1, wherein the external circuitry further comprising a power/ground bus.
 6. The structure in claim 1, wherein the thin-film circuit layer comprising at least a patterned wiring layer and a dielectric layer, the dielectric layer is located on top of the ceramic substrate and the die, and the patterned wiring layer is located on top of the dielectric layer, whereas the patterned wiring layer is electrically connected to the metal pads of the die through the dielectric layer and forms the external circuitry and the bonding pads of the external circuitry.
 7. The structure in claim 6, wherein the dielectric layer has a plurality of thru-holes, and the patterned wiring layer is electrically connected to the metal pads of the die by the thru-holes.
 8. The structure in claim 6, wherein a via is located inside each thru-hole, and the patterned wiring layer is electrically connected to the metal pads of the die by the vias.
 9. The structure in claim 6, wherein the patterned wiring layer and the vias form the external circuitry.
 10. The structure of the claim 6, wherein the external circuitry further comprising at least one passive device.
 11. The structure in claim 6, wherein the passive device is selected from a group consisting of a resistor, an inductor, a capacitor, a wave-guide, a filter, and a micro electronic mechanical sensor (MEMS).
 12. The structure in claim 10, wherein the passive device is formed by a part of the patterned wiring layer.
 13. The structure in claim 6, wherein a material of the dielectric layer is selected from a group consisting of polyimide, benzocyclobutene, porous dielectric material, and stress buffer material.
 14. The structure in claim 1, wherein the thin-film circuit layer comprising a plurality of patterned wiring layers and a plurality of dielectric layers, in which the patterned wiring layers and dielectric layers are alternately formed and the patterned wiring layers are electrically connected to the neighboring patterned wiring layers through the dielectric layer, one of the dielectric layers is formed between the thin-film circuit layer and the ceramic substrate, the patterned wiring layer that is closest to the ceramic substrate is electrically connected to the metal pads of the die through the dielectric layer that is closest to the ceramic substrate, where the patterned wiring layer that is furthest away from the ceramic substrate forms the bonding pads.
 15. The structure in claim 14, wherein each of the dielectric layers has a plurality of thru-holes, by which each of the patterned wiring layer is electrically connected the neighboring patterned wiring layers, where the patterned wiring layer that is closest to the ceramic substrate is electrically connected to the metal pads of the die through the dielectric layer.
 16. The structure in claim 15, wherein a via is located in each thru-hole, by which the patterned wiring layers are electrically connected to the neighboring patterned wiring layers, where the patterned wiring layer that is closest to the ceramic substrate is electrically connected to the metal pads of the die by the vias.
 17. The structure in claim 16, wherein the patterned wiring layers and the vias form the external circuitry.
 18. The structure in claim 14, wherein the external circuitry further comprising a passive device.
 19. The structure in claim 18, wherein the passive device is selected from a group consisting of a resistor, an inductor, a capacitor, a wave-guide, a filter, and a micro electronic mechanical sensor (MEMS).
 20. The structure in claim 18, wherein the passive device is formed by a part of the patterned wiring layer.
 21. The structure in claim 18, wherein a material of the dielectric layer is selected from a group consisting of polyimide, benzocyclobutene, porous dielectric material, and stress buffer material.
 22. The structure in claim 1, wherein the ceramic substrate further comprising an inwardly protruded area located on a surface of the ceramic substrate, where the backside of the die is adhered to a bottom of the inwardly protruded area.
 23. The structure in claim 1, wherein the ceramic substrate comprising a ceramic layer and a heat conducting layer formed overlapping, a surface of the ceramic substrate is a side of the heat conducting layer that is further away from the ceramic layer, the ceramic layer has at least one opening that penetrates through the ceramic layer used to form an inwardly protruded area, and the backside of the die is adhered to a bottom of the inwardly protruded area.
 24. The structure in claim 23, wherein the heat conducting layer comprising a metal.
 25. The structure in claim 1 further comprising a filling layer located between a surface of the ceramic substrate and the thin-film circuit layer and surrounding the peripheral of the die, and a surface of the filling layer is planar to the active surface of the die.
 26. The structure in claim 25, wherein a material of the filling layer is selected from a group consisting of epoxy and polymer.
 27. The structure in claim 1 further comprising a passivation layer located on top of the thin-film circuit layer and exposing the bonding pads.
 28. The structure in claim 1 further comprising a plurality of bonding points located on the bonding pads.
 29. The structure in claim 28, wherein the bonding points are selected from a group consisting of solder balls, bumps, and pins.
 30. A chip package structure comprising: a ceramic substrate; a plurality of dies, wherein each die has an active surface, a backside that is opposite to the active surface, and a plurality of metal pads located on the active surface, whereas the backside of each die is adhered to the ceramic substrate; and a thin-film circuit layer located on top of the ceramic substrate and the die and has an external circuitry, wherein the external circuitry is electrically connected to the metal pads of the die and extends to a region outside the active surface of the die, the external circuitry has a plurality of bonding pads located on a surface layer of the thin-film circuit layer and each bonding pad is electrically connected to the corresponding metal pad of the die.
 31. The structure in claim 30, wherein the dies perform same functions.
 32. The structure in claim 30, wherein the dies perform different functions.
 33. The structure in claim 30, wherein the dies have an internal circuitry and a plurality of active devices located on the active surface of the die, and the internal circuitry is electrically connected to the active devices, whereas the internal circuitry forms the metal pads.
 34. The structure in claim 33, wherein a signal from one of the active devices is transmitted to the external circuitry via the internal circuitry, and from the external circuitry back to one of the active devices via the internal circuitry.
 35. The structure in claim 34, wherein a width, length, and thickness of traces of the external circuitry are greater than corresponding traces of the internal circuitry.
 36. The structure in claim 30, wherein the external circuitry further comprising a power/ground bus.
 37. The structure in claim 30, wherein the thin-film circuit layer comprising at least a patterned wiring layer and a dielectric layer, the dielectric layer is located on top of the ceramic substrate and the die, and the patterned wiring layer is located on top of the dielectric layer, whereas the patterned wiring layer is electrically connected to the metal pads of the die through the dielectric layer and forms the external circuitry and the bonding pads of the external circuitry.
 38. The structure in claim 37, wherein the dielectric layer has a plurality of thru-holes, and the patterned wiring layer is electrically connected to the metal pads of the die by the thru-holes.
 39. The structure in claim 38, wherein a via is located inside each thru-hole, and the patterned wiring layer is electrically connected to the metal pads of the die by the vias.
 40. The structure in claim 39, wherein the patterned wiring layer and the vias form the external circuitry.
 41. The structure of the claim 37, wherein the external circuitry further comprising at least one passive device.
 42. The structure in claim 41, wherein the passive device is selected from a group consisting of a resistor, an inductor, a capacitor, a wave-guide, a filter, and a micro electronic mechanical sensor (MEMS).
 43. The structure in claim 41, wherein the passive device is formed by a part of the patterned wiring layer.
 44. The structure in claim 37, wherein a material of the dielectric layer is selected from a group consisting of polyimide, benzocyclobutene, porous dielectric material, and stress buffer material.
 45. The structure in claim 30, wherein the thin-film circuit layer comprising a plurality of patterned wiring layers and a plurality of dielectric layers, in which the patterned wiring layers and dielectric layers are alternately formed and the patterned wiring layers are electrically connected to the neighboring patterned wiring layers through the dielectric layer, one of the dielectric layers is formed between the thin-film circuit layer and the ceramic substrate, the patterned wiring layer that is closest to the ceramic substrate is electrically connected to the metal pads of the dies through the dielectric layer that is closest to the ceramic substrate, where the patterned wiring layer that is furthest away from the ceramic substrate forms the bonding pads.
 46. The structure in claim 45, wherein each of the dielectric layers has a plurality of thru-holes, by which each of the patterned wiring layer is electrically connected the neighboring patterned wiring layers, where the patterned wiring layer that is closest to the ceramic substrate is electrically connected to the metal pads of the dies through the dielectric layer.
 47. The structure in claim 46, wherein a via is located in each thru-hole, by which the patterned wiring layers are electrically connected to the neighboring patterned wiring layers, where the patterned wiring layer that is closest to the ceramic substrate is electrically connected to the metal pads of the die by the vias.
 48. The structure in claim 47, wherein the patterned wiring layers and the vias form the external circuitry.
 49. The structure in claim 45, wherein the external circuitry further comprising a passive device.
 50. The structure in claim 49, wherein the passive device is selected from a group consisting of a resistor, an inductor, a capacitor, a wave-guide, a filter, and a micro electronic mechanical sensor (MEMS).
 51. The structure in claim 49, wherein the passive device is formed by a part of the patterned wiring layer.
 52. The structure in claim 45, wherein a material of the dielectric layer is selected from a group consisting of polyimide, benzocyclobutene, porous dielectric material, and stress buffer material.
 53. The structure in claim 30, wherein the ceramic substrate further comprising a plurality of inwardly protruded areas located on a surface of the ceramic substrate and the backside of the dies is adhered to a bottom of the inwardly protruded areas.
 54. The structure in claim 30, wherein the ceramic substrate comprising a ceramic layer and a heat conducting layer formed thereon together, a top surface of the ceramic substrate is a side of the heat conducting layer that is further away from the ceramic layer, the ceramic layer has a plurality of openings that penetrate through the ceramic layer used to form the inwardly protruded areas, and the backside of the dies are adhered to a bottom of the inwardly protruded areas.
 55. The structure in claim 54, wherein the heat conducting layer comprising a metal.
 56. The structure in claim 30 further comprising a filling layer located between a surface of the ceramic substrate and the thin-film circuit layer and surrounding the peripheral of the die, and a surface of the filling layer is planar to the active surface of the die.
 57. The structure in claim 56, wherein a material of the filling layer is selected from a group consisting of epoxy and polymer.
 58. The structure in claim 30 further comprising a passivation layer located on top of the thin-film circuit layer and exposing the bonding pads.
 59. The structure in claim 30 further comprising a plurality of bonding points located on the bonding pads.
 60. The structure in claim 59, wherein the bonding points are selected from a group consisting of solder balls, bumps, and pins.
 61. A chip packaging method comprising: providing a ceramic substrate with a surface; providing a plurality of dies, wherein each die has an active surface, a backside that is opposite to the active surface, and a plurality of metal pads located on the active surface, whereas the backside of each die is adhered to the surface of the ceramic substrate; allocating a first dielectric layer on top of the surface of the ceramic substrate and the active surface of the dies; and allocating a first patterned wiring layer on top of the first dielectric layer, wherein the first patterned wiring layer is electrically connected to the metal pads of the dies through the first dielectric layer, extends to a region outside of an area above the active surfaces of the dies, and has a plurality of first bonding pads.
 62. The method of claim 61, wherein the dies perform same functions.
 63. The method of claim 61, wherein the dies perform different functions.
 64. The method of claim 61, wherein the ceramic substrate has a plurality of inwardly protruded areas located on the surface of the ceramic substrate, where the backside of each die is adhered to a bottom of an inwardly protruded area.
 65. The method of claim 64, wherein a depth of the inwardly protruded areas is equal to a thickness of the dies.
 66. The method of claim 64, wherein the inwardly protruded areas are formed by machining.
 67. The method of claim 64, wherein the ceramic substrate comprising at least a first green sheet and a second green sheet placed overlapping and sintered together, and the first green sheet has a plurality of openings used for allocating the inwardly protruded areas when placed on a surface of the second green sheet.
 68. The method of claim 64, wherein the ceramic substrate comprising at least a sintered first green sheet and a second green sheet placed thereon together, and the first green sheet has a plurality of openings used for allocating the inwardly protruded areas when placed on a surface of the second green sheet.
 69. The method of claim 68, wherein the openings are formed before the first green sheet is sintered.
 70. The method of claim 68, wherein the openings are formed after the first green sheet is sintered.
 71. The method of claim 64, wherein the ceramic substrate comprising a ceramic layer and a heat conducting layer formed overlapping, a surface of the ceramic substrate is a side of the heat conducting layer that is further away from the ceramic layer, the ceramic layer has a plurality of openings that penetrates through the ceramic layer used to form the inwardly protruded areas, and the backside of the dies is adhered to a bottom of the inwardly protruded areas.
 72. The method of claim 71, wherein the ceramic layer is formed by sintering a green sheet with the openings formed before the green sheet is sintered.
 73. The method of claim 71, wherein the ceramic layer is formed by sintering a green sheet with the openings formed after the green sheet is sintered.
 74. The method of claim 71, wherein a thickness of the ceramic layer is equal to a thickness of the dies.
 75. The method of claim 71, wherein the heat conducting layer comprising a metal.
 76. The method of claim 61, wherein after adhering the dies and before allocating the first dielectric layer, further comprising allocating a filling layer on top of the surface of the ceramic substrate and surrounding the peripheral of the dies, and a top surface of the filling layer is planar to the active surface of the dies.
 77. The method of claim 76, wherein a material of the filling layer is selected from a group consisting of epoxy and polymer.
 78. The method of claim 61, wherein after allocating the first dielectric layer and before allocating the first patterned wiring layer, further comprising patterning the first dielectric layer to form a plurality of first thru-holes that penetrates through the first dielectric layer, and the first patterned wiring layer is electrically connected to the metal pads of the dies by the first thru-holes.
 79. The method of claim 78, wherein when allocating the first patterned wiring layer on the first dielectric layer, further includes allocating a plurality of first vias by filling part of a conductive material of the first patterned conductive layer into the first thru-holes to electrically connect the first patterned wiring layer and the metal pads of the dies by the first vias.
 80. The method of claim 78, wherein when allocating the first patterned wiring layer on top of the first dielectric layer, further comprising filling the first thru-holes with a conductive material to form a plurality of first vias, by which the first patterned wiring layer and the metal pads are electrically connected.
 81. The method of claim 61, wherein a material of the first dielectric layer is selected from a group consisting of polyimide, benzocyclobutene, porous dielectric material, and stress buffer material.
 82. The method of claim 61, wherein the method of allocating the first patterned wiring layer on top of the first dielectric layer is selected from a group consisting of sputtering, electroplating, and electro-less plating.
 83. The method of claim 61, further comprising allocating a patterned passivation layer on top of the first dielectric layer and the first patterned wiring layer and exposing the first bonding pads.
 84. The method of claim 61, further comprising allocating a bonding point on the first bonding pads.
 85. The method of claim 84, wherein the bonding points are selected from a group consisting of solder balls, bumps, and pins.
 86. The method of claim 84, further comprising singularizing the chip package structure after allocating the bonding point on the bonding pads.
 87. The method of claim 86, wherein a singularization of the chip package structure is performed on a single die.
 88. The method of claim 86, wherein a singularization of the chip package structure is performed on a plurality of dies.
 89. The method of claim 61 further comprising: (a) allocating a second dielectric layer on top of the first dielectric layer and the first patterned wiring layer; and (b) allocating a second patterned wiring layer on top the second dielectric layer, wherein the second patterned wiring layer is electrically connected to the first patterned wiring layer through the second dielectric layer, and the second patterned wiring layer extends to a region outside the active surface of the die and has a plurality of second bonding pads.
 90. The method of claim 89, wherein after allocating the second dielectric layer and before allocating the second patterned wiring layer, further comprising patterning the second dielectric layer to form a plurality of second thru-holes, which corresponds to the first thru-holes and penetrates the second dielectric layer, to electrically connect to the first patterned wiring layer.
 91. The method of claim 90, wherein when allocating the second patterned wiring layer on top of the second dielectric layer, further comprising filling the second thru-holes with part of a conductive material of the second patterned wiring layer to form a plurality of second vias, by which the second patterned wiring layer is electrically connected to the first patterned wiring layer.
 92. The method of claim 90, wherein before allocating the second patterned wiring layer on top of the second dielectric layer, further comprising filling the second thru-holes with a conductive material to form a plurality of second vias, by which the second patterned wiring layer is electrically connected to the first patterned wiring layer.
 93. The method of claim 89, wherein a material of the second dielectric layer is selected from a group consisting of polyimide, benzocyclobutene, porous dielectric material, and stress buffer material.
 94. The method of claim 89, wherein the method of allocating the second patterned wiring layer on the second dielectric layer is selected from a group consisting of sputtering, electroplating, and electro-less plating.
 95. The method of claim 89, further comprising allocating a patterned passivation layer on top of the second dielectric layer and the second patterned wiring layer and exposing the second bonding pads.
 96. The method of claim 89, further comprising allocating a bonding point on the second bonding pads.
 97. The method of claim 96, wherein the bonding points are selected from a group consisting of solder balls, bumps, and pins.
 98. The method of claim 96, further comprising singularizing the chip package structure after allocating the bonding point on the second bonding pads.
 99. The method of claim 98, wherein a singularization of the chip package structure is performed on a single die.
 100. The method of claim 98, wherein a singularization of the chip package structure is performed on a plurality of dies.
 101. The method of claim 89, further comprising repeating step (a) and step (b) a plurality of times.
 102. The method of claim 101 further comprising allocating a patterned passivation layer on the second dielectric layer and the second patterned wiring layer that is furthest away from the ceramic substrate and exposing the second bonding pads of the second patterned wiring layer that is furthest away from the ceramic substrate.
 103. The method of claim 101, further comprising allocating a bonding point on the second bonding pads of the second dielectric layer that is furthest away from the ceramic substrate.
 104. The method of claim 103, wherein the bonding points are selected from a group consisting of solder balls, bumps, and pins.
 105. The method of claim 103, further comprising singularizing the chip package structure after allocating the bonding point on the second bonding pads.
 106. The method of claim 105, wherein a singularization of the chip package structure is performed on a single die.
 107. The method of claim 106, wherein a singularization of the chip package structure is performed on a plurality of dies.
 108. A chip packaging method comprising: providing an insulating substrate with a first surface; providing a plurality of dies, wherein each die has an active surface and a backside that is opposite to the active surface and a plurality of metal pads located on the active surface, whereas the active surface of each die is adhered to the first surface of the insulating substrate; allocating a filling layer on top of the first surface of the insulating substrate and surrounding the dies; planarizing and thinning of the filling layer and the dies; providing a ceramic substrate with a second surface and adhering the second surface of the ceramic substrate to the filling layer and the dies; and allocating a first patterned wiring layer on top of the insulating substrate, wherein the first patterned wiring layer is electrically connected to the metal pads of the dies through the insulating substrate, extends to a region outside the active surfaces of the dies, and has a plurality of first bonding pads.
 109. The method of claim 108, wherein the dies perform same functions.
 110. The method of claim 108, wherein the dies perform different functions.
 111. The method of claim 108, wherein a material of the insulating substrate is selected from a group consisting of glass, ceramic, and organic material.
 112. The method of claim 108, wherein a material of the filling layer is selected from a group consisting of epoxy and polymer.
 113. The method of claim 108, wherein a thickness of the insulating substrate is in a range from about 2 microns to 200 microns.
 114. The method of claim 108, wherein after adhering the ceramic substrate and before patterning the insulating substrate, further comprising thinning a thickness of the insulating substrate.
 115. The method of claim 114, wherein a thickness of the insulating substrate after thinning is in a range from about 2 microns to 200 microns.
 116. The method of claim 108, wherein the method of allocating the first patterned wiring layer on the insulating substrate is selected from a group consisting of sputtering, electroplating, and electro-less plating.
 117. The method of claim 108, wherein before allocating the first patterned wiring layer, further comprising removing part of the insulating substrate to form a plurality of first thru-holes, which correspond to the metal pads and penetrate the insulating substrate, and the first patterned wiring layer is electrically connected to the metal pads by the first thru-holes.
 118. The method of claim 117, wherein when allocating the first patterned wiring layer on the insulating substrate, further comprising filling the first thru-holes with part of a conductive material of the first patterned wiring layer to form a plurality of first vias, by which the first patterned wiring layer is electrically connected to the metal pads of the dies.
 119. The method of claim 117, wherein before allocating the first patterned wiring layer on the insulating substrate, further comprising filling a conductive material in the first thru-holes to form a plurality of first vias, by which the first patterned wiring layer is electrically connected to the metal pads of the dies.
 120. The method of claim 108 further comprising allocating a patterned passivation layer on the insulating substrate and the first patterned wiring layer and exposing the first bonding pads.
 121. The method of claim 108 further comprising allocating a bonding point on the first bonding pads.
 122. The method of claim 121, wherein the bonding points are selected from a group consisting of solder balls, bumps, and pins.
 123. The method of claim 121, further comprising singularizing the chip package structure after allocating the bonding point on the first bonding pads.
 124. The method of claim 123, wherein a singularization of the chip package structure is performed on a single die.
 125. The method of claim 123, wherein a singularization of the chip package structure is performed on a plurality of dies.
 126. The method of claim 108 further comprising: (a) allocating a dielectric layer on top of the insulating substrate and the first patterned wiring layer; and (b) allocating a second patterned wiring layer on top the insulating substrate, wherein the second patterned wiring layer is electrically connected to the first patterned wiring layer through the insulating substrate, and the second patterned wiring layer extends to a region outside of the active surface of the die and has a plurality of second bonding pads.
 127. The method of claim 126, wherein after allocating the dielectric layer and before allocating the second patterned wiring layer, further comprising patterning the dielectric layer to form a plurality of second thru-holes, which corresponds to the first bonding pads and penetrates the dielectric layer, to electrically connect the first patterned wiring layer to the second patterned wiring layer.
 128. The method of claim 127, wherein when allocating the second patterned wiring layer on top of the dielectric layer, further comprising filling the second thru-holes with part of a conductive material of the second patterned wiring layer to form a plurality of second vias, by which the second patterned wiring layer is electrically connected to the first patterned wiring layer.
 129. The method of claim 127, wherein before allocating the second patterned wiring layer on top of the dielectric layer, further comprising filling the second thru-holes with a conductive material to form a plurality of second vias, by which the second patterned wiring layer is electrically connected to the first patterned wiring layer.
 130. The method of claim 126, wherein a material of the dielectric layer is selected from a group consisting of polyimide, benzocyclobutene, porous dielectric material, and stress buffer material.
 131. The method of claim 126, wherein a method of allocating the second patterned wiring layer on the dielectric layer is selected from a group consisting of sputtering, electroplating, and electro-less plating.
 132. The method of claim 126, further comprising allocating a patterned passivation layer on top of the dielectric layer and the second patterned wiring layer and exposing the second bonding pads.
 133. The method of claim 126, further comprising allocating a bonding point on the second bonding pads.
 134. The method of claim 133, wherein the bonding points are selected from a group consisting of solder balls, bumps, and pins.
 135. The method of claim 133, further comprising singularizing the chip package structure after allocating the bonding point on the second bonding pads.
 136. The method of claim 135, wherein a singularization of the chip package structure is performed on a single die.
 137. The method of claim 135, wherein a singularization of the chip package structure is performed on a plurality of dies.
 138. The method of claim 126, further comprising repeating step (a) and step (b) a plurality of times.
 139. The method of claim 138 further comprising allocating a patterned passivation layer on the dielectric layer and the second patterned wiring layer that is furthest away from the ceramic substrate and exposing the second bonding pads of the second patterned wiring layer that is furthest away from the ceramic substrate.
 140. The method of claim 138, further comprising allocating a bonding point on the second bonding pads of the second patterned wiring layer that are furthest away from the ceramic substrate.
 141. The method of claim 140, wherein the bonding points are selected from a group consisting of solder balls, bumps, and pins.
 142. The method of claim 140, further comprising singularizing the chip package structure after allocating the bonding point on the second bonding pads.
 143. The method of claim 142, wherein a singularization of the chip package structure is performed on a single die.
 144. The method of claim 142, wherein a singularization of the chip package structure is performed on a plurality of dies.
 145. A chip packaging method comprising: providing a substrate with a first surface; providing a plurality of dies, wherein each die has an active surface, a backside that is opposite to the active surface, and a plurality of metal pads located on the active surface, whereas the active surface of each die is adhered to the first surface of the substrate; allocating a first filling layer on top of the first surface of the substrate and surrounding the dies; planarizing and thinning of the first filling layer and the dies; providing a ceramic substrate with a second surface and adhering the second surface of the ceramic substrate to the first filling layer and the dies; removing the first filling layer and the substrate; allocating a first dielectric layer on the second surface of the ceramic substrate and the active surface of the dies; and allocating a first patterned wiring layer on top of the first dielectric layer, wherein the first patterned wiring layer is electrically connected to the metal pads of the dies through the first dielectric layer, extends to a region outside the active surfaces of the dies, and has a plurality of first bonding pads.
 146. The method of claim 145, wherein the dies perform same functions.
 147. The method of claim 145, wherein the dies perform different functions.
 148. The method of claim 145, wherein a material of the substrate is selected from a group consisting of glass, ceramic, silicon, and organic material.
 149. The method of claim 145, wherein a material of the first filling layer is selected from a group consisting of epoxy and polymer.
 150. The method of claim 145, wherein after adhering the ceramic substrate and before removing the first filling layer and the substrate, further comprising allocating a second filling layer on top of the second surface of the ceramic substrate, the second filling layer surrounds a peripheral of the dies and has a top surface that is planar to the active surface of the dies.
 151. The method of claim 150, wherein a material of the second filling layer is selected from a group consisting of epoxy and polymer.
 152. The method of claim 145, wherein after allocating the first dielectric layer and before allocating the first patterned wiring layer, further comprising patterning the first dielectric layer to form a plurality of first thru-holes, by which the first patterned wiring layer is electrically connected to the metal pads of the dies.
 153. The method of claim 152, wherein when allocating the first patterned wiring layer on top of the first dielectric layer, further comprising filling the first thru-holes with part of a conductive material of the first patterned wiring layer to form a plurality of first vias, by which the first patterned wiring layer is electrically connected to the metal pads of the dies.
 154. The method of claim 152, wherein before allocating the first patterned wiring layer on top of the first dielectric layer, further comprising filling the first thru-holes with a conductive material to form a plurality of first vias, by which the first patterned wiring layer is electrically connected to the metal pads of the dies.
 155. The method of claim 145, wherein a material of the first dielectric layer is selected from a group consisting of polyimide, benzocyclobutene, porous dielectric material, and stress buffer material.
 156. The method of claim 145, wherein a method of allocating the first patterned wiring layer on the first dielectric layer is selected from a group consisting of sputtering, electroplating, and electro-less plating.
 157. The method of claim 145, further comprising allocating a patterned passivation layer on top of the first dielectric layer and the first patterned wiring layer and exposing the first bonding pads.
 158. The method of claim 145, further comprising allocating a bonding point on the first bonding pads.
 159. The method of claim 158, wherein the bonding points are selected from a group consisting of solder balls, bumps, and pins.
 160. The method of claim 158, further comprising singularizing the chip package structure after allocating the bonding point on the first bonding pads.
 161. The method of claim 160, wherein a singularization of the chip package structure is performed on a single die.
 162. The method of claim 160, wherein a singularization of the chip package structure is performed on a plurality of dies.
 163. The method of claim 145 further comprising: (a) allocating a second dielectric layer on top of the first dielectric layer and the first patterned wiring layer; and (b) allocating a second patterned wiring layer on top the second dielectric layer, wherein the second patterned wiring layer is electrically connected to the first patterned wiring layer through the second dielectric layer, and the second patterned wiring layer extends to a region outside the active surface of the die and has a plurality of second bonding pads.
 164. The method of claim 163, wherein after allocating the second dielectric layer and before allocating the second patterned wiring layer, further comprising patterning the second dielectric layer to form a plurality of second thru-holes, which corresponds to the first bonding pads and penetrates the second dielectric layer, to electrically connect to the first patterned wiring layer.
 165. The method of claim 164, wherein when allocating the second patterned wiring layer on top of the second dielectric layer, further comprising filling the second thru-holes with part of a conductive material of the second patterned wiring layer to form a plurality of second vias, by which the second patterned wiring layer is electrically connected to the first patterned wiring layer.
 166. The method of claim 164, wherein before allocating the second patterned wiring layer on top of the second dielectric layer, further comprising filling the second thru-holes with a conductive material to form a plurality of second vias, by which the second patterned wiring layer is electrically connected to the first patterned wiring layer.
 167. The method of claim 163, wherein a material of the second dielectric layer is selected from a group consisting of polyimide, benzocyclobutene, porous dielectric material, and stress buffer material.
 168. The method of claim 163, wherein a method of allocating the second patterned wiring layer on the second dielectric layer is selected from a group consisting of sputtering, electroplating, and electro-less plating.
 169. The method of claim 163, further comprising allocating a patterned passivation layer on top of the second dielectric layer and the second patterned wiring layer and exposing the second bonding pads.
 170. The method of claim 163, further comprising allocating a bonding point on the second bonding pads.
 171. The method of claim 170, wherein the bonding points are selected from a group consisting of solder balls, bumps, and pins.
 172. The method of claim 170, further comprising singularizing the chip package structure after allocating the bonding point on the second bonding pads.
 173. The method of claim 172, wherein a singularization of the chip package structure is performed on a single die.
 174. The method of claim 172, wherein a singularization of the chip package structure is performed on a plurality of dies.
 175. The method of claim 163, further comprising repeating step (a) and step (b) a plurality of times.
 176. The method of claim 175 further comprising allocating a patterned passivation layer on the second dielectric layer and the second patterned wiring layer that are furthest away from the ceramic substrate and exposing the second bonding pads of the second patterned wiring layer that is furthest away from the ceramic substrate.
 177. The method of claim 175, further comprising allocating a bonding point on the second bonding pads of the second patterned wiring layer that is furthest away from the ceramic substrate.
 178. The method of claim 177, wherein the bonding points are selected from a group consisting of solder balls, bumps, and pins.
 179. The method of claim 177, further comprising singularizing the chip package structure after allocating the bonding point on the second bonding pads.
 180. The method of claim 179, wherein a singularization of the chip package structure is performed on a single die.
 181. The method of claim 179, wherein a singularization of the chip package structure is performed on a plurality of dies.
 182. A chip package structure comprising: a ceramic substrate; a die module comprising an active surface, a backside that is opposite to the active surface, and a plurality of metal pads located on the active surface, whereas the backside of the die module is adhered to the ceramic substrate; a filling layer located on top of the ceramic substrate and surrounding a peripheral of the die module, a top surface of the filling layer is planar to the active surface of the die module; a thin ceramic layer located on top of the filling layer and the die module; and a thin-film circuit layer located on top of the thin ceramic layer and the die module and has an external circuitry, wherein the external circuitry is electrically connected to the metal pads of the die module and extends to a region outside the active surface of the die module, the external circuitry has a plurality of bonding pads located on a surface layer of the thin-film circuit layer and each bonding pad is electrically connected to a corresponding metal pad of the die module.
 183. The structure in claim 182, wherein the die module comprising a single die.
 184. The structure in claim 182, wherein the die module comprising a plurality of dies.
 185. The structure in claim 184, wherein the dies perform different functions.
 186. The structure in claim 182, wherein a material of the filling layer is selected from a group consisting epoxy and polymer.
 187. The structure in claim 188, wherein a thickness of the thin ceramic layer is in a range from about 2 microns to 200 microns.
 188. The structure in claim 182, wherein the die module has an internal circuitry and a plurality of active devices located on the active surface of the die module and the internal circuitry is electrically connected to the active devices, whereas the internal circuitry forms the metal pads.
 189. The structure in claim 188, wherein a signal from one of the active devices is transmitted to the external circuitry via the internal circuitry, and from the external circuitry back to one of the active devices via the internal circuitry.
 190. The structure in claim 189, wherein a width, length, and thickness of traces of the external circuitry are greater than corresponding traces of the internal circuitry.
 191. The structure in claim 182, wherein the external circuitry further comprising a power/ground bus.
 192. The structure in claim 182, wherein the thin-film circuit layer comprising at least a patterned wiring layer, which is located on the thin ceramic layer, whereas the patterned wiring layer is electrically connected to the metal pads of the die module through the thin ceramic layer and forms the external circuitry and the bonding pads of the external circuitry.
 193. The structure in claim 192, wherein the thin ceramic layer has a plurality of thru-holes, and the patterned wiring layer is electrically connected to the metal pads of the die module by the thru-holes.
 194. The structure in claim 193, wherein a via is located inside each thru-hole, and the patterned wiring layer is electrically connected to the metal pads of the die module by the vias.
 195. The structure in claim 194, wherein the patterned wiring layer and the vias form the external circuitry.
 196. The structure of the claim 192, wherein the external circuitry further comprising at least one passive device.
 197. The structure in claim 196, wherein the passive device is selected from a group consisting of a resistor, an inductor, a capacitor, a wave-guide, a filter, and a micro electronic mechanical sensor (MEMS).
 198. The structure in claim 196, wherein the passive device is formed by a part of the patterned wiring layer.
 199. The structure in claim 182, wherein the thin-film circuit layer comprising a plurality of patterned wiring layers and a plurality of dielectric layers, in which the patterned wiring layers and dielectric layers are alternately formed and the patterned wiring layers are electrically connected to the neighboring patterned wiring layers through the dielectric layer, one of the dielectric layers is formed between the thin-film circuit layer and the ceramic substrate, the patterned wiring layer that is closest to the ceramic substrate is electrically connected to the metal pads of the die module through the dielectric layer that is closest to the ceramic substrate, where the patterned wiring layer that is furthest away from the ceramic substrate forms the bonding pads.
 200. The structure in claim 199, wherein the thin ceramic layer has a plurality of first thru-holes, by which the patterned wiring layer that is closest to the ceramic substrate is electrically connected to the metal pads of the die module, and each dielectric layer has a plurality of second thru-holes, by which the patterned wiring layers are electrically connected to the neighboring patterned wiring layers.
 201. The structure in claim 200, wherein a first via is located inside each first thru-hole and a second via is located inside each second thru-hole, and each patterned wiring layer is electrically connected to the neighboring patterned wiring layers by the second vias, wherein the patterned wiring layer that is closest to the ceramic substrate is electrically connected to the metal pads of the die module by the first vias.
 202. The structure in claim 201, wherein the patterned wiring layers, the first vias, and the second vias form the external circuitry.
 203. The structure in claim 199, wherein the external circuitry further comprising a passive device.
 204. The structure in claim 203, wherein the passive device is selected from a group consisting of a resistor, an inductor, a capacitor, a wave-guide, a filter, and a micro electronic mechanical sensor (MEMS).
 205. The structure in claim 199, wherein the passive device is formed by a part of the patterned wiring layer.
 206. The structure in claim 207, wherein a material of the dielectric layer is selected from a group consisting of polyimide, benzocyclobutene, porous dielectric material, and stress buffer material.
 207. The structure in claim 182 further comprising a patterned passivation layer located on top of the thin-film circuit layer and exposing the bonding pads.
 208. The structure in claim 182 further comprising a plurality of bonding points located on the bonding pads.
 209. The structure in claim 208, wherein the bonding points are selected from a group consisting of solder balls, bumps, and pins. 